nom/combinator/mod.rs
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//! General purpose combinators
#![allow(unused_imports)]
#[cfg(feature = "alloc")]
use crate::lib::std::boxed::Box;
use crate::error::{ErrorKind, FromExternalError, ParseError};
use crate::internal::*;
use crate::lib::std::borrow::Borrow;
use crate::lib::std::convert::Into;
#[cfg(feature = "std")]
use crate::lib::std::fmt::Debug;
use crate::lib::std::mem::transmute;
use crate::lib::std::ops::{Range, RangeFrom, RangeTo};
use crate::traits::{AsChar, InputIter, InputLength, InputTakeAtPosition, ParseTo};
use crate::traits::{Compare, CompareResult, Offset, Slice};
#[cfg(test)]
mod tests;
/// Return the remaining input.
///
/// ```rust
/// # use nom::error::ErrorKind;
/// use nom::combinator::rest;
/// assert_eq!(rest::<_,(_, ErrorKind)>("abc"), Ok(("", "abc")));
/// assert_eq!(rest::<_,(_, ErrorKind)>(""), Ok(("", "")));
/// ```
#[inline]
pub fn rest<T, E: ParseError<T>>(input: T) -> IResult<T, T, E>
where
T: Slice<RangeFrom<usize>>,
T: InputLength,
{
Ok((input.slice(input.input_len()..), input))
}
/// Return the length of the remaining input.
///
/// ```rust
/// # use nom::error::ErrorKind;
/// use nom::combinator::rest_len;
/// assert_eq!(rest_len::<_,(_, ErrorKind)>("abc"), Ok(("abc", 3)));
/// assert_eq!(rest_len::<_,(_, ErrorKind)>(""), Ok(("", 0)));
/// ```
#[inline]
pub fn rest_len<T, E: ParseError<T>>(input: T) -> IResult<T, usize, E>
where
T: InputLength,
{
let len = input.input_len();
Ok((input, len))
}
/// Maps a function on the result of a parser.
///
/// ```rust
/// use nom::{Err,error::ErrorKind, IResult,Parser};
/// use nom::character::complete::digit1;
/// use nom::combinator::map;
/// # fn main() {
///
/// let mut parser = map(digit1, |s: &str| s.len());
///
/// // the parser will count how many characters were returned by digit1
/// assert_eq!(parser.parse("123456"), Ok(("", 6)));
///
/// // this will fail if digit1 fails
/// assert_eq!(parser.parse("abc"), Err(Err::Error(("abc", ErrorKind::Digit))));
/// # }
/// ```
pub fn map<I, O1, O2, E, F, G>(mut parser: F, mut f: G) -> impl FnMut(I) -> IResult<I, O2, E>
where
F: Parser<I, O1, E>,
G: FnMut(O1) -> O2,
{
move |input: I| {
let (input, o1) = parser.parse(input)?;
Ok((input, f(o1)))
}
}
/// Applies a function returning a `Result` over the result of a parser.
///
/// ```rust
/// # use nom::{Err,error::ErrorKind, IResult};
/// use nom::character::complete::digit1;
/// use nom::combinator::map_res;
/// # fn main() {
///
/// let mut parse = map_res(digit1, |s: &str| s.parse::<u8>());
///
/// // the parser will convert the result of digit1 to a number
/// assert_eq!(parse("123"), Ok(("", 123)));
///
/// // this will fail if digit1 fails
/// assert_eq!(parse("abc"), Err(Err::Error(("abc", ErrorKind::Digit))));
///
/// // this will fail if the mapped function fails (a `u8` is too small to hold `123456`)
/// assert_eq!(parse("123456"), Err(Err::Error(("123456", ErrorKind::MapRes))));
/// # }
/// ```
pub fn map_res<I: Clone, O1, O2, E: FromExternalError<I, E2>, E2, F, G>(
mut parser: F,
mut f: G,
) -> impl FnMut(I) -> IResult<I, O2, E>
where
F: Parser<I, O1, E>,
G: FnMut(O1) -> Result<O2, E2>,
{
move |input: I| {
let i = input.clone();
let (input, o1) = parser.parse(input)?;
match f(o1) {
Ok(o2) => Ok((input, o2)),
Err(e) => Err(Err::Error(E::from_external_error(i, ErrorKind::MapRes, e))),
}
}
}
/// Applies a function returning an `Option` over the result of a parser.
///
/// ```rust
/// # use nom::{Err,error::ErrorKind, IResult};
/// use nom::character::complete::digit1;
/// use nom::combinator::map_opt;
/// # fn main() {
///
/// let mut parse = map_opt(digit1, |s: &str| s.parse::<u8>().ok());
///
/// // the parser will convert the result of digit1 to a number
/// assert_eq!(parse("123"), Ok(("", 123)));
///
/// // this will fail if digit1 fails
/// assert_eq!(parse("abc"), Err(Err::Error(("abc", ErrorKind::Digit))));
///
/// // this will fail if the mapped function fails (a `u8` is too small to hold `123456`)
/// assert_eq!(parse("123456"), Err(Err::Error(("123456", ErrorKind::MapOpt))));
/// # }
/// ```
pub fn map_opt<I: Clone, O1, O2, E: ParseError<I>, F, G>(
mut parser: F,
mut f: G,
) -> impl FnMut(I) -> IResult<I, O2, E>
where
F: Parser<I, O1, E>,
G: FnMut(O1) -> Option<O2>,
{
move |input: I| {
let i = input.clone();
let (input, o1) = parser.parse(input)?;
match f(o1) {
Some(o2) => Ok((input, o2)),
None => Err(Err::Error(E::from_error_kind(i, ErrorKind::MapOpt))),
}
}
}
/// Applies a parser over the result of another one.
///
/// ```rust
/// # use nom::{Err,error::ErrorKind, IResult};
/// use nom::character::complete::digit1;
/// use nom::bytes::complete::take;
/// use nom::combinator::map_parser;
/// # fn main() {
///
/// let mut parse = map_parser(take(5u8), digit1);
///
/// assert_eq!(parse("12345"), Ok(("", "12345")));
/// assert_eq!(parse("123ab"), Ok(("", "123")));
/// assert_eq!(parse("123"), Err(Err::Error(("123", ErrorKind::Eof))));
/// # }
/// ```
pub fn map_parser<I, O1, O2, E: ParseError<I>, F, G>(
mut parser: F,
mut applied_parser: G,
) -> impl FnMut(I) -> IResult<I, O2, E>
where
F: Parser<I, O1, E>,
G: Parser<O1, O2, E>,
{
move |input: I| {
let (input, o1) = parser.parse(input)?;
let (_, o2) = applied_parser.parse(o1)?;
Ok((input, o2))
}
}
/// Creates a new parser from the output of the first parser, then apply that parser over the rest of the input.
///
/// ```rust
/// # use nom::{Err,error::ErrorKind, IResult};
/// use nom::bytes::complete::take;
/// use nom::number::complete::u8;
/// use nom::combinator::flat_map;
/// # fn main() {
///
/// let mut parse = flat_map(u8, take);
///
/// assert_eq!(parse(&[2, 0, 1, 2][..]), Ok((&[2][..], &[0, 1][..])));
/// assert_eq!(parse(&[4, 0, 1, 2][..]), Err(Err::Error((&[0, 1, 2][..], ErrorKind::Eof))));
/// # }
/// ```
pub fn flat_map<I, O1, O2, E: ParseError<I>, F, G, H>(
mut parser: F,
mut applied_parser: G,
) -> impl FnMut(I) -> IResult<I, O2, E>
where
F: Parser<I, O1, E>,
G: FnMut(O1) -> H,
H: Parser<I, O2, E>,
{
move |input: I| {
let (input, o1) = parser.parse(input)?;
applied_parser(o1).parse(input)
}
}
/// Optional parser, will return `None` on [`Err::Error`].
///
/// To chain an error up, see [`cut`].
///
/// ```rust
/// # use nom::{Err,error::ErrorKind, IResult};
/// use nom::combinator::opt;
/// use nom::character::complete::alpha1;
/// # fn main() {
///
/// fn parser(i: &str) -> IResult<&str, Option<&str>> {
/// opt(alpha1)(i)
/// }
///
/// assert_eq!(parser("abcd;"), Ok((";", Some("abcd"))));
/// assert_eq!(parser("123;"), Ok(("123;", None)));
/// # }
/// ```
pub fn opt<I: Clone, O, E: ParseError<I>, F>(mut f: F) -> impl FnMut(I) -> IResult<I, Option<O>, E>
where
F: Parser<I, O, E>,
{
move |input: I| {
let i = input.clone();
match f.parse(input) {
Ok((i, o)) => Ok((i, Some(o))),
Err(Err::Error(_)) => Ok((i, None)),
Err(e) => Err(e),
}
}
}
/// Calls the parser if the condition is met.
///
/// ```rust
/// # use nom::{Err, error::{Error, ErrorKind}, IResult};
/// use nom::combinator::cond;
/// use nom::character::complete::alpha1;
/// # fn main() {
///
/// fn parser(b: bool, i: &str) -> IResult<&str, Option<&str>> {
/// cond(b, alpha1)(i)
/// }
///
/// assert_eq!(parser(true, "abcd;"), Ok((";", Some("abcd"))));
/// assert_eq!(parser(false, "abcd;"), Ok(("abcd;", None)));
/// assert_eq!(parser(true, "123;"), Err(Err::Error(Error::new("123;", ErrorKind::Alpha))));
/// assert_eq!(parser(false, "123;"), Ok(("123;", None)));
/// # }
/// ```
pub fn cond<I, O, E: ParseError<I>, F>(
b: bool,
mut f: F,
) -> impl FnMut(I) -> IResult<I, Option<O>, E>
where
F: Parser<I, O, E>,
{
move |input: I| {
if b {
match f.parse(input) {
Ok((i, o)) => Ok((i, Some(o))),
Err(e) => Err(e),
}
} else {
Ok((input, None))
}
}
}
/// Tries to apply its parser without consuming the input.
///
/// ```rust
/// # use nom::{Err,error::ErrorKind, IResult};
/// use nom::combinator::peek;
/// use nom::character::complete::alpha1;
/// # fn main() {
///
/// let mut parser = peek(alpha1);
///
/// assert_eq!(parser("abcd;"), Ok(("abcd;", "abcd")));
/// assert_eq!(parser("123;"), Err(Err::Error(("123;", ErrorKind::Alpha))));
/// # }
/// ```
pub fn peek<I: Clone, O, E: ParseError<I>, F>(mut f: F) -> impl FnMut(I) -> IResult<I, O, E>
where
F: Parser<I, O, E>,
{
move |input: I| {
let i = input.clone();
match f.parse(input) {
Ok((_, o)) => Ok((i, o)),
Err(e) => Err(e),
}
}
}
/// returns its input if it is at the end of input data
///
/// When we're at the end of the data, this combinator
/// will succeed
///
/// ```
/// # use std::str;
/// # use nom::{Err, error::ErrorKind, IResult};
/// # use nom::combinator::eof;
///
/// # fn main() {
/// let parser = eof;
/// assert_eq!(parser("abc"), Err(Err::Error(("abc", ErrorKind::Eof))));
/// assert_eq!(parser(""), Ok(("", "")));
/// # }
/// ```
pub fn eof<I: InputLength + Clone, E: ParseError<I>>(input: I) -> IResult<I, I, E> {
if input.input_len() == 0 {
let clone = input.clone();
Ok((input, clone))
} else {
Err(Err::Error(E::from_error_kind(input, ErrorKind::Eof)))
}
}
/// Transforms Incomplete into `Error`.
///
/// ```rust
/// # use nom::{Err,error::ErrorKind, IResult};
/// use nom::bytes::streaming::take;
/// use nom::combinator::complete;
/// # fn main() {
///
/// let mut parser = complete(take(5u8));
///
/// assert_eq!(parser("abcdefg"), Ok(("fg", "abcde")));
/// assert_eq!(parser("abcd"), Err(Err::Error(("abcd", ErrorKind::Complete))));
/// # }
/// ```
pub fn complete<I: Clone, O, E: ParseError<I>, F>(mut f: F) -> impl FnMut(I) -> IResult<I, O, E>
where
F: Parser<I, O, E>,
{
move |input: I| {
let i = input.clone();
match f.parse(input) {
Err(Err::Incomplete(_)) => Err(Err::Error(E::from_error_kind(i, ErrorKind::Complete))),
rest => rest,
}
}
}
/// Succeeds if all the input has been consumed by its child parser.
///
/// ```rust
/// # use nom::{Err,error::ErrorKind, IResult};
/// use nom::combinator::all_consuming;
/// use nom::character::complete::alpha1;
/// # fn main() {
///
/// let mut parser = all_consuming(alpha1);
///
/// assert_eq!(parser("abcd"), Ok(("", "abcd")));
/// assert_eq!(parser("abcd;"),Err(Err::Error((";", ErrorKind::Eof))));
/// assert_eq!(parser("123abcd;"),Err(Err::Error(("123abcd;", ErrorKind::Alpha))));
/// # }
/// ```
pub fn all_consuming<I, O, E: ParseError<I>, F>(mut f: F) -> impl FnMut(I) -> IResult<I, O, E>
where
I: InputLength,
F: Parser<I, O, E>,
{
move |input: I| {
let (input, res) = f.parse(input)?;
if input.input_len() == 0 {
Ok((input, res))
} else {
Err(Err::Error(E::from_error_kind(input, ErrorKind::Eof)))
}
}
}
/// Returns the result of the child parser if it satisfies a verification function.
///
/// The verification function takes as argument a reference to the output of the
/// parser.
///
/// ```rust
/// # use nom::{Err,error::ErrorKind, IResult};
/// use nom::combinator::verify;
/// use nom::character::complete::alpha1;
/// # fn main() {
///
/// let mut parser = verify(alpha1, |s: &str| s.len() == 4);
///
/// assert_eq!(parser("abcd"), Ok(("", "abcd")));
/// assert_eq!(parser("abcde"), Err(Err::Error(("abcde", ErrorKind::Verify))));
/// assert_eq!(parser("123abcd;"),Err(Err::Error(("123abcd;", ErrorKind::Alpha))));
/// # }
/// ```
pub fn verify<I: Clone, O1, O2, E: ParseError<I>, F, G>(
mut first: F,
second: G,
) -> impl FnMut(I) -> IResult<I, O1, E>
where
F: Parser<I, O1, E>,
G: Fn(&O2) -> bool,
O1: Borrow<O2>,
O2: ?Sized,
{
move |input: I| {
let i = input.clone();
let (input, o) = first.parse(input)?;
if second(o.borrow()) {
Ok((input, o))
} else {
Err(Err::Error(E::from_error_kind(i, ErrorKind::Verify)))
}
}
}
/// Returns the provided value if the child parser succeeds.
///
/// ```rust
/// # use nom::{Err,error::ErrorKind, IResult};
/// use nom::combinator::value;
/// use nom::character::complete::alpha1;
/// # fn main() {
///
/// let mut parser = value(1234, alpha1);
///
/// assert_eq!(parser("abcd"), Ok(("", 1234)));
/// assert_eq!(parser("123abcd;"), Err(Err::Error(("123abcd;", ErrorKind::Alpha))));
/// # }
/// ```
pub fn value<I, O1: Clone, O2, E: ParseError<I>, F>(
val: O1,
mut parser: F,
) -> impl FnMut(I) -> IResult<I, O1, E>
where
F: Parser<I, O2, E>,
{
move |input: I| parser.parse(input).map(|(i, _)| (i, val.clone()))
}
/// Succeeds if the child parser returns an error.
///
/// ```rust
/// # use nom::{Err,error::ErrorKind, IResult};
/// use nom::combinator::not;
/// use nom::character::complete::alpha1;
/// # fn main() {
///
/// let mut parser = not(alpha1);
///
/// assert_eq!(parser("123"), Ok(("123", ())));
/// assert_eq!(parser("abcd"), Err(Err::Error(("abcd", ErrorKind::Not))));
/// # }
/// ```
pub fn not<I: Clone, O, E: ParseError<I>, F>(mut parser: F) -> impl FnMut(I) -> IResult<I, (), E>
where
F: Parser<I, O, E>,
{
move |input: I| {
let i = input.clone();
match parser.parse(input) {
Ok(_) => Err(Err::Error(E::from_error_kind(i, ErrorKind::Not))),
Err(Err::Error(_)) => Ok((i, ())),
Err(e) => Err(e),
}
}
}
/// If the child parser was successful, return the consumed input as produced value.
///
/// ```rust
/// # use nom::{Err,error::ErrorKind, IResult};
/// use nom::combinator::recognize;
/// use nom::character::complete::{char, alpha1};
/// use nom::sequence::separated_pair;
/// # fn main() {
///
/// let mut parser = recognize(separated_pair(alpha1, char(','), alpha1));
///
/// assert_eq!(parser("abcd,efgh"), Ok(("", "abcd,efgh")));
/// assert_eq!(parser("abcd;"),Err(Err::Error((";", ErrorKind::Char))));
/// # }
/// ```
pub fn recognize<I: Clone + Offset + Slice<RangeTo<usize>>, O, E: ParseError<I>, F>(
mut parser: F,
) -> impl FnMut(I) -> IResult<I, I, E>
where
F: Parser<I, O, E>,
{
move |input: I| {
let i = input.clone();
match parser.parse(i) {
Ok((i, _)) => {
let index = input.offset(&i);
Ok((i, input.slice(..index)))
}
Err(e) => Err(e),
}
}
}
/// if the child parser was successful, return the consumed input with the output
/// as a tuple. Functions similarly to [recognize](fn.recognize.html) except it
/// returns the parser output as well.
///
/// This can be useful especially in cases where the output is not the same type
/// as the input, or the input is a user defined type.
///
/// Returned tuple is of the format `(consumed input, produced output)`.
///
/// ```rust
/// # use nom::{Err,error::ErrorKind, IResult};
/// use nom::combinator::{consumed, value, recognize, map};
/// use nom::character::complete::{char, alpha1};
/// use nom::bytes::complete::tag;
/// use nom::sequence::separated_pair;
///
/// fn inner_parser(input: &str) -> IResult<&str, bool> {
/// value(true, tag("1234"))(input)
/// }
///
/// # fn main() {
///
/// let mut consumed_parser = consumed(value(true, separated_pair(alpha1, char(','), alpha1)));
///
/// assert_eq!(consumed_parser("abcd,efgh1"), Ok(("1", ("abcd,efgh", true))));
/// assert_eq!(consumed_parser("abcd;"),Err(Err::Error((";", ErrorKind::Char))));
///
///
/// // the first output (representing the consumed input)
/// // should be the same as that of the `recognize` parser.
/// let mut recognize_parser = recognize(inner_parser);
/// let mut consumed_parser = map(consumed(inner_parser), |(consumed, output)| consumed);
///
/// assert_eq!(recognize_parser("1234"), consumed_parser("1234"));
/// assert_eq!(recognize_parser("abcd"), consumed_parser("abcd"));
/// # }
/// ```
pub fn consumed<I, O, F, E>(mut parser: F) -> impl FnMut(I) -> IResult<I, (I, O), E>
where
I: Clone + Offset + Slice<RangeTo<usize>>,
E: ParseError<I>,
F: Parser<I, O, E>,
{
move |input: I| {
let i = input.clone();
match parser.parse(i) {
Ok((remaining, result)) => {
let index = input.offset(&remaining);
let consumed = input.slice(..index);
Ok((remaining, (consumed, result)))
}
Err(e) => Err(e),
}
}
}
/// Transforms an [`Err::Error`] (recoverable) to [`Err::Failure`] (unrecoverable)
///
/// This commits the parse result, preventing alternative branch paths like with
/// [`nom::branch::alt`][crate::branch::alt].
///
/// # Example
///
/// Without `cut`:
/// ```rust
/// # use nom::{Err,error::ErrorKind, IResult};
/// # use nom::character::complete::{one_of, digit1};
/// # use nom::combinator::rest;
/// # use nom::branch::alt;
/// # use nom::sequence::preceded;
/// # fn main() {
///
/// fn parser(input: &str) -> IResult<&str, &str> {
/// alt((
/// preceded(one_of("+-"), digit1),
/// rest
/// ))(input)
/// }
///
/// assert_eq!(parser("+10 ab"), Ok((" ab", "10")));
/// assert_eq!(parser("ab"), Ok(("", "ab")));
/// assert_eq!(parser("+"), Ok(("", "+")));
/// # }
/// ```
///
/// With `cut`:
/// ```rust
/// # use nom::{Err,error::ErrorKind, IResult, error::Error};
/// # use nom::character::complete::{one_of, digit1};
/// # use nom::combinator::rest;
/// # use nom::branch::alt;
/// # use nom::sequence::preceded;
/// use nom::combinator::cut;
/// # fn main() {
///
/// fn parser(input: &str) -> IResult<&str, &str> {
/// alt((
/// preceded(one_of("+-"), cut(digit1)),
/// rest
/// ))(input)
/// }
///
/// assert_eq!(parser("+10 ab"), Ok((" ab", "10")));
/// assert_eq!(parser("ab"), Ok(("", "ab")));
/// assert_eq!(parser("+"), Err(Err::Failure(Error { input: "", code: ErrorKind::Digit })));
/// # }
/// ```
pub fn cut<I, O, E: ParseError<I>, F>(mut parser: F) -> impl FnMut(I) -> IResult<I, O, E>
where
F: Parser<I, O, E>,
{
move |input: I| match parser.parse(input) {
Err(Err::Error(e)) => Err(Err::Failure(e)),
rest => rest,
}
}
/// automatically converts the child parser's result to another type
///
/// it will be able to convert the output value and the error value
/// as long as the `Into` implementations are available
///
/// ```rust
/// # use nom::IResult;
/// use nom::combinator::into;
/// use nom::character::complete::alpha1;
/// # fn main() {
///
/// fn parser1(i: &str) -> IResult<&str, &str> {
/// alpha1(i)
/// }
///
/// let mut parser2 = into(parser1);
///
/// // the parser converts the &str output of the child parser into a Vec<u8>
/// let bytes: IResult<&str, Vec<u8>> = parser2("abcd");
/// assert_eq!(bytes, Ok(("", vec![97, 98, 99, 100])));
/// # }
/// ```
pub fn into<I, O1, O2, E1, E2, F>(mut parser: F) -> impl FnMut(I) -> IResult<I, O2, E2>
where
O1: Into<O2>,
E1: Into<E2>,
E1: ParseError<I>,
E2: ParseError<I>,
F: Parser<I, O1, E1>,
{
//map(parser, Into::into)
move |input: I| match parser.parse(input) {
Ok((i, o)) => Ok((i, o.into())),
Err(Err::Error(e)) => Err(Err::Error(e.into())),
Err(Err::Failure(e)) => Err(Err::Failure(e.into())),
Err(Err::Incomplete(e)) => Err(Err::Incomplete(e)),
}
}
/// Creates an iterator from input data and a parser.
///
/// Call the iterator's [ParserIterator::finish] method to get the remaining input if successful,
/// or the error value if we encountered an error.
///
/// On [`Err::Error`], iteration will stop. To instead chain an error up, see [`cut`].
///
/// ```rust
/// use nom::{combinator::iterator, IResult, bytes::complete::tag, character::complete::alpha1, sequence::terminated};
/// use std::collections::HashMap;
///
/// let data = "abc|defg|hijkl|mnopqr|123";
/// let mut it = iterator(data, terminated(alpha1, tag("|")));
///
/// let parsed = it.map(|v| (v, v.len())).collect::<HashMap<_,_>>();
/// let res: IResult<_,_> = it.finish();
///
/// assert_eq!(parsed, [("abc", 3usize), ("defg", 4), ("hijkl", 5), ("mnopqr", 6)].iter().cloned().collect());
/// assert_eq!(res, Ok(("123", ())));
/// ```
pub fn iterator<Input, Output, Error, F>(input: Input, f: F) -> ParserIterator<Input, Error, F>
where
F: Parser<Input, Output, Error>,
Error: ParseError<Input>,
{
ParserIterator {
iterator: f,
input,
state: Some(State::Running),
}
}
/// Main structure associated to the [iterator] function.
pub struct ParserIterator<I, E, F> {
iterator: F,
input: I,
state: Option<State<E>>,
}
impl<I: Clone, E, F> ParserIterator<I, E, F> {
/// Returns the remaining input if parsing was successful, or the error if we encountered an error.
pub fn finish(mut self) -> IResult<I, (), E> {
match self.state.take().unwrap() {
State::Running | State::Done => Ok((self.input, ())),
State::Failure(e) => Err(Err::Failure(e)),
State::Incomplete(i) => Err(Err::Incomplete(i)),
}
}
}
impl<'a, Input, Output, Error, F> core::iter::Iterator for &'a mut ParserIterator<Input, Error, F>
where
F: FnMut(Input) -> IResult<Input, Output, Error>,
Input: Clone,
{
type Item = Output;
fn next(&mut self) -> Option<Self::Item> {
if let State::Running = self.state.take().unwrap() {
let input = self.input.clone();
match (self.iterator)(input) {
Ok((i, o)) => {
self.input = i;
self.state = Some(State::Running);
Some(o)
}
Err(Err::Error(_)) => {
self.state = Some(State::Done);
None
}
Err(Err::Failure(e)) => {
self.state = Some(State::Failure(e));
None
}
Err(Err::Incomplete(i)) => {
self.state = Some(State::Incomplete(i));
None
}
}
} else {
None
}
}
}
enum State<E> {
Running,
Done,
Failure(E),
Incomplete(Needed),
}
/// a parser which always succeeds with given value without consuming any input.
///
/// It can be used for example as the last alternative in `alt` to
/// specify the default case.
///
/// ```rust
/// # use nom::{Err,error::ErrorKind, IResult};
/// use nom::branch::alt;
/// use nom::combinator::{success, value};
/// use nom::character::complete::char;
/// # fn main() {
///
/// let mut parser = success::<_,_,(_,ErrorKind)>(10);
/// assert_eq!(parser("xyz"), Ok(("xyz", 10)));
///
/// let mut sign = alt((value(-1, char('-')), value(1, char('+')), success::<_,_,(_,ErrorKind)>(1)));
/// assert_eq!(sign("+10"), Ok(("10", 1)));
/// assert_eq!(sign("-10"), Ok(("10", -1)));
/// assert_eq!(sign("10"), Ok(("10", 1)));
/// # }
/// ```
pub fn success<I, O: Clone, E: ParseError<I>>(val: O) -> impl Fn(I) -> IResult<I, O, E> {
move |input: I| Ok((input, val.clone()))
}
/// A parser which always fails.
///
/// ```rust
/// # use nom::{Err, error::ErrorKind, IResult};
/// use nom::combinator::fail;
///
/// let s = "string";
/// assert_eq!(fail::<_, &str, _>(s), Err(Err::Error((s, ErrorKind::Fail))));
/// ```
pub fn fail<I, O, E: ParseError<I>>(i: I) -> IResult<I, O, E> {
Err(Err::Error(E::from_error_kind(i, ErrorKind::Fail)))
}